Portable electronic device having directional proximity sensors based on device orientation

ABSTRACT

A portable electronic device having one or more proximity sensors. The portable electronic device comprises a housing, one or more signal emitters to direct source signal(s) based on the orientation of the housing, and one or more signal receivers to receive return signals corresponding to the source signal(s). The device may include multiple signal emitters and a sensor to identify an orientation of the housing. The appropriate signal emitter may be selected based on the orientation of the housing as identified by the sensor.

RELATED APPLICATIONS

The present application is a continuation of and commonly assigned U.S. application Ser. No. 12/347,146, to Rachid M. Alameh, et al., filed on Dec. 31, 2008, titled PORTABLE ELECTRONIC DEVICE HAVING DIRECTIONAL PROXIMITY SENSORS BASED ON DEVICE ORIENTATION, from which benefits under 35 U.S.C. §120 are hereby claimed and the contents of to which are incorporated herein by reference. In addition, this application is related to U.S. application Ser. No. 12/344,760, to Rachid M. Alameh, et al., filed Dec. 29, 2008, titled PORTABLE ELECTRONIC DEVICE HAVING SELF-CALIBRATING PROXIMITY SENSORS, now U.S. Pat. No. 8,030,914, granted Oct. 4, 2011.

FIELD OF THE INVENTION

The present invention relates generally to the field of electronic devices having one or more proximity sensors. More particularly, the present invention relates to a wireless communication device having one or more proximity sensors with directional capabilities.

BACKGROUND OF THE INVENTION

Proximity sensors are capable of detecting the presence of nearby objects without any physical contact. In particular, a proximity sensor emits an electromagnetic or electrostatic field, and observes changes in the field. In doing so, the proximity sensor detects any position changes of nearby objects based on changes to the electromagnetic or electrostatic field caused by the objects' presence.

Wireless communication devices may utilize proximity sensors to manage the user experience and power consumption of its audio and video output components when adjacent to a user's ear. In particular, these devices may reduce speaker volume when the device's earpiece is positioned near the user's ear to avoid discomfort to the user's eardrums. As another example, the proximity sensor may turn off the device display when the device is positioned near the user's ear to save power. Thus, these types of wireless communication device dynamically adjust the operation of audio and video output components when these components are positioned very close to, i.e., adjacent to, a user's ear.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a general representation of an example environmental condition where the present invention may be utilized.

FIG. 2 is a perspective view of an embodiment in accordance with the present invention.

FIG. 3 a block diagram representing example components that may be used for an embodiment in accordance with the present invention.

FIGS. 4A, 4B and 4C are flow diagrams representing operations of an embodiment in accordance with the present invention.

FIG. 5 is a graphical representation illustrating the results of an example operation of an embodiment in accordance with the present invention.

FIG. 6 is a block diagram representing an example circuit for minimizing the impact of background noise in accordance with the present invention.

FIG. 7 is a sectional view, through line 7-7′ of FIG. 2, illustrating an example embodiment of the proximity sensors in accordance with the present invention.

FIG. 8 is a partial sectional illustrating another example embodiment of the proximity sensors in accordance with the present invention.

FIG. 9 is a representative view of a first position of the example embodiment of FIG. 8.

FIG. 10 is a representative view of a second position of the example embodiment of FIG. 8.

DETAILED DESCRIPTION OF THE EMBODIMENTS

There is described portable electronic device having one or more sensors with self-calibration capabilities. In particular, each proximity sensor of the device is capable of dynamically deriving a detection threshold as a portion of received background conditions. The sensors of the self-calibrating device dynamically adjust its own power consumption based on the environment conditions surrounding the device, resulting to minimized power consumption. In addition, the sensors of the self-calibrating, low power device are capable of monitoring a broad range of environmental conditions, i.e., far away as well as nearby, surrounding the device due to its ultra-sensitivity, resulting in optimized functionality. The ultra-sensitivity of the sensors is accomplished by detecting near noise level or, more particularly, by setting the detection threshold just above the noise level as a portion of the received signal, allowing for detection of miniscule disturbances.

The proximity sensors of the portable electronic device in accordance with the present invention may operate in multiple, different modes. These modes are context driven and the area of coverage, such as, range, angle, and active sensors, may be adaptively set and adjusted based on input from other sensors of the device. Context information may be used to set the range and/or coverage of each proximity sensor to achieve the desired functionality while keeping power consumption to a minimum. For example, if the portable electronic device is positioned near the user's head, the set range of the proximity sensor may be minimized and applications may be disabled, such as operations of an input component, to conserve power. If the portable communication device is operating in a two-handed user mode, the sensors may detect which hand of the user is supporting the back of the device, estimate the device location relative to the user, disable select sensors, increase the range of select sensors, and the like. If the portable electronic device is placed on a horizontal surface, such as a table, the proximity sensors may be adjusted to operate at maximum range and monitor to detect any disturbances which may indicate user presence. Also, the proximity sensors may be used to determine which side of the device the user is walking near and, in response, deactivate the remaining proximity sensors, i.e., those sensors directed away from the user. If portable electronic device is face down on a horizontal surface, i.e., a user interface is not visible to proximate users, the proximity sensors directed upward relate to the surface may be active and the remaining sensors may be disabled.

One aspect of the present invention is a portable electronic device comprising multiple signal emitters in which the appropriate signal emitter may be selected based on the orientation of the device. The portable electronic device comprises a housing, one or more sensors supported by the housing, first and second signal emitter supported by the housing, one or more signal receivers supported by the housing, and a processor supported by the housing. The sensor(s) identify an orientation of the housing. The first signal emitter directs a first source signal in a first direction, and the second signal emitter directs a second source signal in a second direction different from the first direction. The signal receiver(s) receive first and second return signals corresponding to the first and second source signals, respectively. The processor determines which of the first and second signal emitters to activate based on the orientation of the housing as identified by the sensor(s).

Another aspect of the present invention comprises multiple signal receivers in which the appropriate signal receiver may be selected based on the orientation of the device. The portable electronic device comprises a housing, one or more sensors supported by the housing, one or more signal emitters supported by the housing, first and second signal receivers supported by the housing, and a processor supported by the housing. The sensor(s) identify an orientation of the housing. The signal emitter(s) emit a source signal. The first signal receiver receives a return signal corresponding to the source signal from a first direction, and the second signal receiver receives the return signal corresponding to the source signal from a second direction different from the first direction. The processor determines which of the first and second signal receivers to activate based on the orientation of the housing as identified by the sensor(s).

Referring to FIG. 1, there is shown a general representation of an example environmental condition where the present invention may be utilized. A portable electronic device 101 in accordance with the present invention may be carried by a user or, as shown in FIG. 1, placed remote from the user. For example, the portable electronic device 101 may be placed on another object, such as a horizontal surface 103. The portable electronic device 101 may use its proximity sensors to detect conditions in an environment 105 when the device is carried by the user or placed remote from the user, the device is particularly useful when it is stationary. Proximity sensors of the portable electronic device 101 are capable of detecting the presence of nearby objects, particularly when the objects change position relative to the device. For example, the proximity sensors are capable of detecting the slightest movement of people 107, 109 locating within the environment 105 in the proximity of the device 101. Some people 107 may be nearby the device 101, whereas others may be distal from the device.

Referring to FIG. 2, there is illustrated a perspective view of an embodiment in accordance with the present invention. The embodiment may be any type of portable electronic device 201 having one or more proximity sensors and capability of performing self-calibration functions of the proximity sensor(s) in accordance with the present invention. Examples of the portable electronic device 201 include, but are not limited to, cellular-based mobile phones, WLAN-based mobile phones, notebook or laptop computing devices, personal digital assistants, personal navigation device, touch screen input device, pen-based input devices, portable video and/or audio players, and the like.

For one embodiment, the portable electronic device 201 has a housing comprising a front surface 203 which includes a visible display 205 which may include touch screen capabilities. For another embodiment, the portable electronic device 201 may include a plurality of input keys in conjunction with the display 205. For yet another embodiment, the portable electronic device 201 may comprise apertures 207, 209 for audio output and input at the front surface 203. It is to be understood that the portable electronic device 201 may include a variety of different combination of displays and interfaces.

In addition to the front surface 203, the housing of the portable electronic device 201 may also include a top surface 211, a bottom surface 213, side surfaces 215, 217, and a back surface 219. The top surface 211, the bottom surface 213, the side surfaces 215, 217 of the housing of the portable electronic device 201 are not required to have any particular shape or configuration relative to the front and back surfaces 203 and 219.

The front surface 203, the top surface 211, the bottom surface 213, the side surfaces 215, 217, and the back surface 219 of the housing may support one or more proximity sensors. Although some proximity sensors may be exposed at a surface of the housing, it is recognized that some types of proximity sensors may function while concealed behind a surface of the housing. If the portable electronic device 201 includes two or more proximity sensors, then proximity sensors may be positioned at different surfaces of the housing in order to maximize the broadest detection coverage of the conditions about the environment 105. For example, the proximity sensors may be positioned at opposing surface, so that one sensor may be directed in a first direction and another sensor may be directed in a second direction substantially opposite the first direction. Proximity sensors can also be co-located at the same area of the housing, or the same substrate supported by the housing, but directed in different directions.

Referring to FIG. 3, there is shown a block diagram representing example components that may be used for an embodiment in accordance with the present invention. The example embodiment includes one or more wireless transceivers 301, a processor 303, a memory 305, one or more output components 307, and one or more input components 309. Each embodiment may include a user interface that comprises one or more output components 307 and one or more input components 309. Each wireless transceiver 301 may utilize wireless technology for communication, such as, but are not limited to, cellular-based communications such as analog communications (using AMPS), digital communications (using CDMA, TDMA, GSM, iDEN, GPRS, or EDGE), and next generation communications (using UMTS, WCDMA, LTE or IEEE 802.16) and their variants, as represented by cellular transceiver 311. Each wireless transceiver 301 may also utilize wireless technology for communication, such as, but are not limited to, peer-to-peer or ad hoc communications such as HomeRF, Bluetooth and IEEE 802.11(a, b, g or n); and other forms of wireless communication such as infrared technology, as represented by WLAN transceiver 313. Also, each transceiver 201 may be a receiver, a transmitter or both.

The processor 303 may generate commands based on information received from one or more input components 309 and one or more sensors 315. The processor 303 may process the received information alone or in combination with other data, such as the information stored in the memory 305. Thus, the memory 305 of the internal components 300 may be used by the processor 303 to store and retrieve data. The data that may be stored by the memory 305 include, but is not limited to, operating systems, applications, and data. Each operating system includes executable code that controls basic functions of the portable electronic device, such as interaction among the components of the internal components 300, communication with external devices via each transceiver 301 and/or the device interface (see below), and storage and retrieval of applications and data to and from the memory 305. Each application includes executable code utilizes an operating system to provide more specific functionality for the portable electronic device. Data is non-executable code or information that may be referenced and/or manipulated by an operating system or application for performing functions of the portable electronic device. For example, the processor 303 may retrieve information the memory 305 to calibrate the sensitivity of the sensors 315.

The input components 309 of the internal components 300 may include a video input component such as an optical sensor (for example, a camera), an audio input component such as a microphone, and a mechanical input component such as button or key selection sensors, touch pad sensor, touch screen sensor, capacitive sensor, motion sensor, and switch. Likewise, the output components 307 of the internal components 300 may include a variety of video, audio and/or mechanical outputs. For example, the output components 307 may include a video output component such as a cathode ray tube, liquid crystal display, plasma display, incandescent light, fluorescent light, front or rear projection display, and light emitting diode indicator. Other examples of output components 307 include an audio output component such as a speaker, alarm and/or buzzer, and/or a mechanical output component such as vibrating or motion-based mechanisms.

The sensors 315 are similar to the input components 309, but are particularly identified separately in FIG. 3 due to their importance for the present invention. The portable electronic device 100, in accordance with the present invention, may include at least one proximity sensor 315 to detect the presence of nearby objects. For example, as illustrated by FIG. 2, the sensors 315 may include one or more proximity sensors 317 such as, but not limited to, capacitive, magnetic, inductive, optical/photoelectric, laser, acoustic/sonic, radar-based, Doppler-based, thermal, and radiation-based proximity sensors. For example, the proximity sensor 317 may be an infrared proximity sensor that transmits a beam of infrared (IR) light, and then computes the distance to any nearby objects from characteristics of the returned, reflected signal. The returned signal may be detected using an IR photodiode to detect reflected light emitting diode (LED) light, responding to modulated IR signals, and/or triangulation. The sensors 315 may also include one or more other sensors 319. Examples of these other sensors 319 include, but are not limited to, accelerometers, touch sensors, surface/housing capacitive sensors, audio sensors, and video sensors (such as a camera). For example, an accelerometer may be embedded in the electronic circuitry of the portable electronic device 201 to show vertical orientation, constant tilt and/or whether the device is stationary. Touch sensors may used to indicate whether the device is being touched at the side surfaces 215, 217, thus indicating whether or not certain orientations or movements are intentional by the user.

The internal components 300 may further include a device interface 321 to provide a direct connection to auxiliary components or accessories for additional or enhanced functionality. In addition, the internal components 300 preferably include a power source 323, such as a portable battery, for providing power to the other internal components and allow portability of the portable electronic device 101.

It is to be understood that FIG. 3 is provided for illustrative purposes only and for illustrating components of a portable electronic device in accordance with the present invention, and is not intended to be a complete schematic diagram of the various components required for a portable electronic device. Therefore, a portable electronic device may include various other components not shown in FIG. 3, or may include a combination of two or more components or a division of a particular component into two or more separate components, and still be within the scope of the present invention.

Referring to FIG. 4A, there is shown a flow diagram representing a first operation 400 of an embodiment in accordance with the present invention. For this first operation 400, the portable electronic device 101 obtains a background measurement each time before one or more proximity sensors are activated. At step 401, one or more proximity sensors 317 of the portable electronic device 101 obtain a background measurement. As shown in FIG. 4A, a background measurement may be taken before each magnitude measurement for the detection threshold. A background measurement is a measurement of the received signal when no signal is being transmitted by the proximity sensor(s) 317. For another embodiment, statistics of the background may be accumulated and used to determine an appropriate threshold for the magnitude measurement. The accumulated statistic includes at least one of mean, standard deviation, maximum signal level, or minimum signal level. The threshold can then adaptively change as the environment changes and, thus, is reflected in the background measurements. If a random noise spike does occur during a magnitude measurement that exceeds the threshold, the processor 303 or proximity sensor 317 may obtain additional information from other sensor 319 to determine if the magnitude measurement was corrupted.

After obtaining the background measurement at step 401, the portable electronic device 101 may determine whether the background measurements warrant an adjustment to the detection threshold of one or more proximity sensor 317 at step 403. The portable electronic device 101 may update the detection threshold every time a background measurement is obtained, but adjustment of the detection threshold may only be necessary when the background measurement indicates a change. The portable electronic device 101 may also decide to adjust the detection threshold by identifying the background measurement as exceeding a predetermined noise threshold. Further, as stated above, the portable electronic device 101 may distinguish movement from nearby objects from random noise spikes or corrupt measurements to avoid adjusting the detection threshold unnecessarily or inappropriately.

If the adjustment is warranted, then the portable electronic device 101 may adjust the detection threshold of one or more proximity sensors 317 based on the background measurement at step 405. The detection threshold is associated with a sensitivity of the proximity sensor 317 to environmental conditions, which may be detected by sensors 319 other than the proximity sensor(s) 317. Also, the same detection threshold may be used for multiple proximity sensors 317, or separate detections thresholds for different proximity sensors. The portable electronic device 101 may determine an appropriate detection threshold based on information from a sensor 319 other than the proximity sensor in conjunction with the background measurement by the proximity sensor(s) 317. Examples of sensors 319 other than the proximity sensor(s) 317 includes, but at not limited to, a touch sensor, a light sensor or an accelerometer. The portable electronic device 101 may also determine an appropriate detection threshold based on date information, time information, or both, in conjunction with the background measurement by the proximity sensor(s) 317.

The portable electronic device 101 may adjust the detection threshold based on a predetermined fraction, percentage, ratio or other calculation based on the background measurement. The portable electronic device 101 may also dynamically adjust the detection threshold lower for even better detection results based on information received from other sensors 319, such as, but not limited to, time of day, use habits, environment, in use status showing receiver output was unchanged for a long time, time of day prediction if a user is expected to be asleep, etc.

Regardless of whether or not the detection threshold of the proximity sensor(s) 317 is adjusted, the first operation 400 continues by emitting a source signal by the proximity sensor based on the adjusted detection threshold of the proximity sensor at step 407, and receiving a return signal by the proximity sensor corresponding to the source signal at step 409. The portable electronic device 101 may perform one or more functions based on the return signal at step 411. For example, the device 101 may activate an output component 307, such as an audio, visual and/or mechanical indicator, in order to attract the attention of a nearby person. As another example, the device 101 activate or keep active one or more functions if movement of a nearby object is detected, or otherwise deactivate functions to conserve energy if no movement is detected. Thereafter, the portable electronic device 101 may obtain another background measurement at step 401 or wait a predetermined time period at step 413 before obtaining another background measurement.

Referring to FIG. 4B, there is shown another flow diagram representing a to second operation 420 of an embodiment in accordance with the present invention. For this second operation 420, the portable electronic device 101 obtains a background measurement independent of when one or more proximity sensors are activated. Each proximity sensor 317 may emit a source signal at step 421, and receive a return signal corresponding to the source signal at step 423. After a predetermined time period at step 425, the device 101 may continue to emit the source signal and receive the return signal repeatedly. Similar to the first operation 400 above, the portable electronic device 101 may perform one or more functions based on the return signal after step 423.

Separately, the portable electronic device 101 may obtain a background measurement by the proximity sensor on a periodic basis. After obtaining the background measurement at step 427, the portable electronic device 101 may determine whether the background measurements warrant an adjustment to the detection threshold of one or more proximity sensor 317 at step 429. If the adjustment is warranted at step 429, then the portable electronic device 101 may adjust the detection threshold of one or more proximity sensors 317 based on the background measurement at step 431. For this second operation 420, the emission/receiving process would have a link 435 to the detection threshold adjustment process, so that the adjusted detection threshold may be utilized the next time the source signal is emitted at step 421. Finally, the detection threshold adjustment process may include a delay of time at step 422 before obtaining the next background measurement at step 427.

Referring to FIG. 4C, there is shown yet another flow diagram representing a third operation 440 of an embodiment in accordance with the present invention. For this third operation 440, the portable electronic device 101 obtains a background measurement after a predetermined number of times when one or more proximity sensors are activated, or in response to detecting a change in the environmental conditions.

After obtaining the background measurement at step 441, the portable electronic device 101 may determine whether the background measurements warrant an adjustment to the detection threshold of one or more proximity sensor 317 at step 443. If the adjustment is warranted, then the portable electronic device 101 may adjust the detection threshold of one or more proximity sensors 317 based on the background measurement at step 445. Regardless of whether or not the detection threshold of the proximity sensor(s) 317 is adjusted, the third operation 440 continues by emitting a source signal by the proximity sensor based on the adjusted detection threshold of the proximity sensor at step 447, and receiving a return signal by the proximity sensor corresponding to the source signal at step 449. Similar to the first and second operations 400, 420 above, the portable electronic device 101 may perform one or more functions based on the return signal after step 449.

Thereafter, the portable electronic device 101 may determine whether another background measurement should be obtained at step 451. For example, the device 101 may include a counter, so that the device may obtain a background measurement after a certain number of source signals have been emitted and a certain number of return signals have been received. For another example, the device 101 initiate a background measure only if a sensor 319 other than the proximity sensor(s) 317 provide information indicating a change in the environmental conditions about the device. The third operation 440 continues at step 441 if a background check is desired, and the third operation continues at step 447 if a background check is not needed. Also, the portable electronic device 101 may wait a predetermined time period at step 453 or step 455 before obtaining another background measurement or emitting another source signal.

The example operation may be represented by the following possible scenario. A user may place the portable electronic device 101 on a table, and leave it there as she or he moves away from it. When the user 107 approaches the device 101, the device detects, at a lower power mode, user presence and which side user is approaching. The lower power mode may, for example, be achieved by extending the duration between pulses, higher sensitivity such as transmitting high peak, and/or wider signal, e.g., LED, pulses. The portable electronic device 101 detects being stationary on a horizontal surface 103 and detect its orientation. Regarding the orientation, an accelerometer for example may not detect change and may indicate whether the device is upside down or right side up, and touch sensors may detect contact or lack thereof. The device 101 then initiates bursts at the proximity sensors at maximum power or a predetermined high-power level. If the device 101 includes more that two proximity sensors, then the proximity sensors to activate or keep active are selected based on the orientation of the device. The maximum or high-level power bursts may be enabled, since the device 101 is expected to be far from the user for this scenario. The bursting may be initiated right away, i.e., as soon as device 101 is placed down or after certain time delay to increase the chance that the receivers of the proximity sensors start to measure quiescent/background returns.

Referring to FIG. 5, there is shown a graphical representation illustrating the results of an example operation 500 of an embodiment in accordance with the present invention. The horizontal axis 501 of this graphical representation represents time, in seconds, and the vertical axis 503 of this graphical representation represents output, in volts. For this operation 500, the operation of the portable electronic device 101 is context driven, where the device is positioned on a horizontal surface 103. Also, for this operation 500, the portable electronic device 101 includes a proximity sensor 317 at opposing sides, such as a first proximity sensor 505 at the first side 215 and a second proximity sensor 507 at the second side 217 opposite the first side. In FIG. 5, the first proximity sensor 505 and the first side 215 is identified as “Left RX”, and the second proximity sensor 507 at the second side 217 is identified as “Right RX”.

The processor 303 reads the receiver outputs of both proximity sensors 505, 507, and continues to take readings periodically. The processor 303 then observes the values that are similar, or within a pre-defined range, for each of the outputs. These readings correspond to circuit bias, background interference/lighting, and/or user presence. A reading of “1” is mostly constant in this operation 500 and should represent the situation where the user (or anyone else) is away from the portable electronic device 101. The processor 303 then sets a user detection threshold as a percentage of “1”, i.e., self-calibrates itself. The processor 303 also detects which side the user is detected by the device 101. For example, the determination of the side of detection may be used to direct audio or rotate an image toward the user when she or he comes near. This is done by looking at receiver outputs of both proximity sensors 505, 507.

The processor 303 may use the same detection threshold for multiple proximity sensors, or separate detections thresholds for different proximity sensors. For example, the right side detection threshold for the first proximity sensor 505 may, be 1.00 volts+delta. Thus, if the delta, by way of example, is predetermined at 1/10 or 10%, then the right side detection threshold may be set at 1.1 volts of output. For another example, the left side detection threshold for the second proximity sensor 507 may be 1.20 volts+delta. Thus, if the delta is, again, predetermined at 1/10 or 10%, then the left side detection threshold may be set at 1.32 volts of output.

For the embodiment represented by FIG. 5, the processor 303 measures, for the first three seconds of operation, a voltage reading 509 of 1.00 volt at the first proximity sensor 505 and a voltage reading 511 of 1.20 volts at the second proximity sensor 507. The non-varying characteristic of these first and second voltage readings 509, 511 indicate that movement by objects in the environment 105 surrounding the device 101 is not detected by the proximity sensors 505, 507. For example, the user 107 may have been away from portable electronic device 101 for first three seconds.

For the next two seconds of operation, i.e., the 4th and 5th seconds, the voltage readings 513, 515 at the first proximity sensor 505 increases to, and levels-off at, 1.30 volts, thus indicating that the first proximity sensor detects significant movement for that two second period of time. During that same time period, the voltage reading 517 at the second proximity sensor 507 increases slightly to 1.22 volts and then another voltage reading 519 at the second proximity sensor decreases even more slightly to 1.21 volts. The slight detection at the second proximity sensor 507, when considered by itself, would not necessarily indicate any type of detection of an object, i.e., user, in proximity of the sensor. However, when this slight detection of the second proximity sensor 507 is considered in conjunction with the detection at the first proximity sensor 505, these two readings indicate that movement is detected by both proximity sensors, in which the location of the detected object relative to the device 101 may be determined based on the sensor detecting the greater percentage change. For example, the user 107 may walk by the right side 217 of the portable electronic device 101 for two seconds, which may have been detected by the proximity sensor at the right side 217. The movement by the right side 217 of the user 107 may have also caused a minor disturbance, which may have been detected by the proximity sensor at the left side 215.

For the following two seconds of operation, i.e., the 6th and 7th seconds, the voltage readings 521, 523 at the first proximity sensor 505 decreases back down to, and levels-off at, the previous voltage level, i.e., to 1.00 volts, thus indicating that the first proximity sensor no longer detects movement for that two second period of time. During that same time period, the voltage readings 525, 527 at the second proximity sensor 507 increases substantially to, and levels-off at, 2.00 volts. The substantial increase in signal detection by the second proximity sensor 507 indicates higher energy motion or motion by multiple objects at the second side 217 of the portable electronic device 101. Also, in contrast to the previous time period where changes were detected by both proximity sensors 505, 507, the detection by the second proximity sensor and the lack of detection by the first proximity sensor indicates that all detection motion is at the second side 217 of the device 101. For example, the user 107 may further walk by the left side 215 of the portable electronic device 101 for two seconds.

For the last two seconds of operation, i.e., the 8th and 9th seconds, the voltage readings of the first proximity sensor 505 remain unchanged and the voltage readings 529 and 531 of the second proximity sensor 507 decreases back down to, and level-off at, the previous, initial voltage level, i.e., to 1.2 volts. Accordingly, the receiver outputs of both proximity sensors 505, 507 indicate that the proximity sensors no longer detect movement for that two second period of time. For example, the user 107 may have further moved away from the portable electronic device 101. If the background changes to a new level, such as the room or environment becomes illuminated by a light source, then the sensors should indicate a sudden increase of light that remains relatively constant, which indicates that the change in environment is due to background, as opposed to user presence.

A background measurement may be taken before each magnitude measurement for the detection threshold. A background measurement is a to measurement of the received signal when no signal is being transmitted. The background measurement provides a measure of the noise. Statistics of the background are accumulated (e.g. average, standard deviation, max, min, etc.) and used to determine an appropriate threshold for the magnitude measurement. The threshold can then adaptively change as the environment changes and is reflected in the background measurements. If a random noise spike does occur during a magnitude measurement that exceeds the threshold, coding which, for example, may look for predefined a pulse stream or code, will provide additional information to know if the magnitude measurement is corrupted.

Referring to FIG. 6, a coding circuit 600 may be implemented to minimize the impact of background noise. Coding by the circuit 600 is performed by transmitting multiple coding pulses, in which the receiver knows the timing of the coding pulses, and checking for whether a particular signal is present or not present in the returning or received signal 601 at the appropriate time. For example, a proximity sensor may send four coding pulses, and the coding circuit may determining the validity of the returning signal 601 corresponding to these four coding pulses based on the timing of the coding pulses of the returning signal. If the pulses of the received signal 601 are received properly, the magnitude measurement 603 is considered to be valid; otherwise, the magnitude measurement may be corrupt. For example, an optical proximity sensor may be corrupted by extraneous light sources in the environment, such as light flashes from another device. If the magnitude measurement 603 is valid, then it may be used to determine the detection threshold as described above. The detection threshold of the proximity sensor may be adjusted based on the magnitude measurement in response to determining that the return signal meets or exceeds a predetermined criterion, as described below.

The magnitude measurement 603 is taken soon after the coding pulses are transmitted. A sample and hold circuit 605 is used to sample the magnitude of the received signal when one of the pulses is transmitted. For example, a peak detector may be used as a sample and hold circuit. The output of the sample and hold circuit 605 may be input to an analog-to-digital (“A-to-D”) converter 607. It should be noted that the sample and hold circuit 605 may be separate from the A-to-D converter 607 as shown in FIG. 6, or the circuit may integrated in the A-to-D converter. The sample and hold circuit 605 may be used to reduce the timing requirements of the A-to-D converter 607. The width of the transmitted coding pulses may be minimized, since the sample and hold circuit 605 is aware of the timing when the pulses are transmitted which, in turn, saves current drain of components that consume a significant amount of current, such as the transmitter.

The coding circuit 600 may also check signal validity 609 as well as the magnitude measurement 603. The coding circuit 600 determines whether the return signal meets or exceeds a predetermined criterion based on timing of the multiple pulses. For example, as illustrated in FIG. 6, the signal validity 609 may be checked in parallel with the magnitude measurement 603, and both checks may be based on the received signal 601. To receive the coding pulses, the received signal 601 may be input to a comparator 611, and converted to a digital signal that is input to a GPIO line of a microprocessor 613. The microprocessor 613 then reads the GPIO line at the appropriate time to determine if the coding pulses are present. Using a comparator 611 to identify the coding pulses (instead of, for example, the A-to-D converter 607) maximizes the speed in performing the complete measurement, thus saving current drain. The microprocessor 613 may optionally avoid using code at low received signal levels in order to further maximize performance and minimize current drain.

In accordance with the above, the coding circuit 600 performs two functions. For one, the multiple transmitted coding pulses are connected together as a single wide pulse via a sample and hold circuit 605 and used to measure received signal strength, i.e., magnitude measurement 603. The resulting wide pulse amplitude changes with signal strength and is used to assess user distance from the portable electronic device. For the other, the multiple pulses are applied to a comparator 611 whose output is digital signal. The digital signal may show multiple digital pulses indicating that it is valid signal, since the microprocessor 613 counts the multiple pulses within a set interval instead of random noise edges. Accordingly, falsing is minimized, while processing and detection speed are improved and power drain is minimized.

Referring to FIG. 7, there is shown a sectional view of the portable electronic device 201, which illustrates an example embodiment 700 of the proximity sensors in accordance with the present invention. For this embodiment, the portable electronic device 201 comprises a housing 701 which supports a pair of signal emitters 703, 705 and one or more signal receivers 707. For example, the housing 701 of the portable electronic device 201 may support a first signal emitter 703, a second signal emitter 705 and a signal receiver 707. In the alternative, the housing 701 may support more than one pair of signal emitters and/or more than one signal receiver. For example, the housing 701 of the portable electronic device 201 may support a first signal emitter 703, a second signal emitter 705, a third signal emitter 709, a fourth signal emitter 711, a first signal receiver 707 and a second signal receiver 713.

The sensor of the portable electronic device 201, such as sensor 319, identifies an orientation of the housing. The state of the sensor enables and disables power to proximity sensor for minimizing power consumption of the device 201. Any type of sensor capable of detecting acceleration and/or gravitational forces may use used to identify housing orientation such as, but not limited to, an accelerometer. The processor 303 of the portable electronic device 201 determines which of the first and second signal emitters to activate based on the orientation of the housing as identified by the sensor.

As stated above, the portable electronic device 201 comprises the first signal emitter 703, the second signal emitter 705, and one or more signal receivers 707. The first signal emitter 703 directs a first source signal in a first direction, and the second signal emitter 705 directs a second source signal in a second direction different from the first direction. The signal receiver or receivers 707 receive first and second return signals corresponding to the first and second source signals, respectively.

As described above, the housing 701 comprises the front surface 203, the first side surface 215, the second side surface 217, and the back surface 219. The housing comprises a first side, represented by front surface 203, and a second side, represented by back surface 219, substantially opposite the first side. The sensor of the portable electronic device 201, such as sensor 319, identifies an orientation of the housing. The orientation comprises a first orientation in which the first side of the housing 701 to is directed upward, and the second side of the housing is directed downward. The orientation also comprises a second orientation in which the second side of the housing 701, represented by back surface 219, is directed upward, and the first side of the housing, represented by front surface 203, is directed downward. The first side of the housing 701 includes a user interface, represented by display 205, and the second side of the housing is devoid of any user interface. The housing 701 may further comprise a third side, represented by first side surface 215, and a fourth side substantially opposite the third side, represented by second side surface 217, in which the third and fourth sides are substantially orthogonal to the first and second sides.

The housing 701 of the portable electronic device 201 may support multiple pairs of signal emitters and/or multiple signal receivers. For example, the first signal emitter 703, the second signal emitter 705 and the signal receiver 707 may be located proximate to the third side, i.e., surface 215, of the housing 701. In addition, the third signal emitter 709, the fourth signal emitter 711, and a second signal receiver 713 may be located proximate to the fourth side, i.e., surface 217, of the housing 701, in which the fourth side is substantially opposite the third side. Likewise, the orientation of the housing 701 comprises first and second orientations. For the first orientation, the first and third signal emitters 703, 709 are directed upward but different directions, and the second and fourth signal emitters 705, 711 are directed downward but different directions. For the second orientation, the second and fourth signal emitters are directed upward but different directions, and the first and third signal emitters are directed downward but different directions. For example, as shown in FIG. 7, the first signal emitter 703 is directed to an upper left area external to the housing 701, the second signal emitter 705 is directed to a lower left area external to the housing, the third signal emitter 709 is directed to an upper right area external to the housing, and the fourth signal emitter 711 is directed to a lower right area external to the housing.

For another embodiment in accordance with the present invention, the housing 701 of the portable electronic device 201 may support multiple signal receivers, in addition to or instead of the multiple signal emitters, in which the appropriate signal receiver may be selected based on the orientation of the device. For example, the housing may support first, second, third and/or fourth signal receivers at the positions shown in FIG. 7 for signal emitters 703, 705, 709 and/or 711. The first signal receiver may receive a return signal corresponding to a source signal from a first direction, and the second signal receiver may receive the return signal corresponding to the source signal from a second direction different from the first direction. A processor 303 may determines which of the first and second signal receivers to activate based on the orientation of the housing as identified by the sensor(s).

Referring to FIG. 8, there is shown another example embodiment 800 of the proximity sensors in accordance with the present invention, in which a mechanism is used to redirect a source signal from a signal emitter 801 in an appropriate direction based on the orientation of the housing 701. The mechanism includes a compartment 803 located adjacent to the signal emitter 801, and a reflector 805 supported by the compartment. The reflector 805 may shift between the first and second positions in the compartment 803, illustrated by FIGS. 9 and 10 as described below, based on a gravitational force subjected to the reflector. The gravitational force changes as the orientation of the housing is altered. 16. The gravity-driven mechanism may be used to keep active emitters directed upward and disable emitters directed downward since the device may be placed on a surface, which exposes the upward sensors but hinders the downward sensors. The gravity-driven mechanism may also allow a single signal emitter to be directed in multiple directions, thus minimizing the number of signal emitters, and their associated cost, needed for a desired area of coverage by each proximity sensor. In yet another embodiment, an accelerometer may be used to enable upward directed transmitters and/or receivers and disable other transmitters and/or receivers that are not directed upward.

Similar to the embodiment described above, the first side of the housing 701 may includes a user interface, represented by display 205, and the second side of the housing is devoid of any user interface. The housing 701 may further comprise multiple pairs of signal emitters and/or multiple signal receivers.

For one embodiment, the compartment 803 may include a hollow bore, and the reflector 805 may slide in the hollow bore when shifting between the first and second positions in the compartment. The compartment 803 may be elongated along a longitudinal axis 807, in which the longitudinal axis is substantially orthogonal to the first and second sides, represented by surfaces 203, 218, of the housing 701. The reflector 805 may travel along the longitudinal axis 807 when shifting between the first and second positions. A source signal 809 from the signal emitter 801 may be redirected by the reflector 805 based on the orientation of the housing 701.

For another embodiment in accordance with the present invention, the housing 701 of the portable electronic device 201 may support components that determine an appropriate direction to receive a return signal corresponding to a source signal based on the orientation of the housing, so that the return signal may be redirected to the signal receiver. For example, the housing 701 may support a signal receiver at the position shown in FIG. 8 for signal emitter 801. The housing 701 may support a reflector 805 adjacent to the signal receiver that has a first position relative to the signal receiver to receive the return signal corresponding to the source signal from a first direction and redirect the return signal to the signal receiver. The reflector may also have a second position relative to the signal receiver to receive the return signal corresponding to the source signal from a second direction different from the first direction and redirect the return signal to the signal receiver. The different positions of the reflector relative to the signal emitter or signal receiver, as well as the changing directions of the source signal and return signal, are illustrated by the explanation below regarding FIGS. 9 and 10.

Referring to FIG. 9, there is shown a representative view of a first position 900 of the example embodiment of FIG. 8. For this first position 900, a signal emitter 901 directs a source signal 903 to a reflector 905. For the embodiment shown in FIG. 9, the reflector 905 is triangular in shape and includes a first reflective surface 907 and a second reflective surface 909. The reflector 905 may have a first position 900 in the compartment 803 to direct the source signal 903 from the signal emitter 901 in a first direction 911. The second reflective surface 909 is angled and is capable of reflecting the source signal 903 in a directed relative to the angle of the second reflective surface.

The portable electronic device 201 may be subjected to a gravitational force which may cause the reflector 905 shift in a direction 913 toward the gravitational force. The most common gravitational force is generally directed downward relative to the portable electronic device 201. For the embodiment shown in FIG. 9, the gravitation force is above the reflector 905, and so the “downward” gravitational force is actually upward in FIG. 9. When the second side of the housing 701 is directed upward and the first side of the housing is directed downward, the reflector shifts to the first position 900 in the direction 913 toward the gravitational force. The source signal 903 reflects at the second reflective surface 909 in response to the reflector 905 shirting to the first position 900.

Referring to FIG. 10, there is shown a representative view of a second position 1000 of the example embodiment of FIG. 8. For this second position 1000, the signal emitter 901 directs the source signal 903 to the reflector 905. The reflector 905 may have a second position 1000 in the compartment 803 to direct the source signal 903 from the signal emitter 901 in a second direction 1011. The first reflective surface 907 is angled and is capable of reflecting the source signal 903 in a directed relative to the angle of the first reflective surface.

The portable electronic device 201 may be subjected to a gravitational force which may cause the reflector 905 shift in a direction 1013 toward the gravitational force. FIGS. 9 and 10 show the two possible reflector positions driven by gravity. Regardless of the orientation of the portable electronic device, the signal emitter(s) always points upward by reflecting off the appropriate surface, such as surface 907, of the reflector as the reflector slides downward due to the gravitational force. If the orientation of the portable electronic device is changed, i.e., the device is placed upside down, the signal emitter(s) points upward again by reflecting off the other surface, such as surface 909. The gravitation force when the reflector 905 shifts to the second position 1000 is different from the direction 913 when the reflector shifts to the first position 900 because the gravitational force changes as the orientation of the housing 701 is altered. For the embodiment shown in FIG. 10, the gravitation force is below the reflector 905, and so the downward gravitational force is downward in FIG. 10. When the first side of the housing 701 is directed upward and the second side of the housing is directed downward, the reflector shifts to the second position 1000 in the direction 1013 toward the gravitational force. The source signal 903 reflects at the first reflective surface 907 in response to the reflector 905 shirting to the second position 1000. The re and a second position in the compartment to direct the source signal from the signal emitter in a second direction different from the first direction.

While the preferred embodiments of the invention have been illustrated and described, it is to be understood that the invention is not so limited. Numerous modifications, changes, variations, substitutions and equivalents will occur to those skilled in the art without departing from the spirit and scope of the present invention as defined by the appended claims. 

1. A portable electronic device having one or more proximity sensors, the portable electronic device comprising: a housing; at least one sensor supported by the housing, the at least one sensor to identify an orientation of the housing; a first signal emitter supported by the housing, the first signal emitter to emit a first source signal in a first direction; a second signal emitter supported by the housing, the second signal emitter to emit a second source signal in a second direction different from the first direction; at least one signal receiver supported by the housing, the at least one signal receiver to receive first and second return signals corresponding to the first and second source signals, respectively; and a processor supported by the housing, the processor to determine which of the first and second signal emitters to activate based on the orientation of the housing as identified by the at least one sensor.
 2. The portable electronic device of claim 1, wherein the at least one sensor includes at least one of an accelerometer, a touch sensor, an audio sensor, or a visible sensor.
 3. The portable electronic device of claim 1, wherein the housing comprises a first side and a second side substantially opposite the first side.
 4. The portable electronic device of claim 3, wherein the orientation comprises: a first orientation wherein the first side of the housing is directed upward, and the second side of the housing is directed downward; and a second orientation wherein the second side of the housing is directed upward, and the first side of the housing is directed downward.
 5. The portable electronic device of claim 3, wherein the first side of the housing includes a user interface and the second side of the housing is devoid of any user interface.
 6. The portable electronic device of claim 3, wherein: the housing comprises a third side and a fourth side substantially opposite the third side, the third and fourth sides being substantially orthogonal to the first and second sides; the first signal emitter, the second signal emitter and the at least one signal receiver are located proximate to the third side of the housing; and a third signal emitter, a fourth signal emitter and at least one other signal receiver are located proximate to the fourth side of the housing.
 7. The portable electronic device of claim 6, wherein the orientation comprises: a first orientation wherein the first and third signal emitters are directed upward but different directions, and the second and fourth signal emitters are directed downward but different directions; and a second orientation wherein the second and fourth signal emitters are directed upward but different directions, and the first and third signal emitters are directed downward but different directions.
 8. A portable electronic device having one or more proximity sensors, the portable electronic device comprising: a housing; at least one sensor supported by the housing, the at least one sensor to identify an orientation of the housing; at least one signal emitter supported by the housing, the at least one signal emitter to emit a source signal; a first signal receiver supported by the housing, the first signal receiver to receive a return signal corresponding to the source signal from a first direction; a second signal receiver supported by the housing, the second signal receiver to receive the return signal corresponding to the source signal from a second direction different from the first direction; and a processor supported by the housing, the processor to determine which of the first and second signal receivers to activate based on the orientation of the housing as identified by the at least one sensor. 